HU215810B - Absorbent articles containing superabsorbent material which has a delayed activation time - Google Patents

Abstract

PCT No. PCT/SE94/00572 Sec. 371 Date Dec. 5, 1995 Sec. 102(e) Date Dec. 5, 1995 PCT Filed Jun. 13, 1994 PCT Pub. No. WO95/00183 PCT Pub. Date Jan. 5, 1995An absorbent structure in an absorbent article, such as a diaper, incontinence guard, sanitary napkin and the like, wherein the structure includes hydrophilic fibres and particles of a superabsorbent material and also has a front and a back part (4, 5) and a crotch part (6) located therebetween, said crotch part exhibiting a wetting region (16) within which the major part of discharged fluid is directed and wherein the absorbent structure in the wetting region includes superabsorbent particles that are encased in a material that will only dissolve slowly in and/or be penetrated slowly by the fluid to be absorbed so that the superabsorbent material will not begin to absorb fluid and swell to any appreciable extent until the encapsulating material has dissolved and/or been penetrated by the fluid and that conventional superabsorbent material (15) is localized generally in those parts of the structure that are located outside said wetting region.

Description

The present invention thus relates to an absorbent structure for an absorbent article, such as a diaper, incontinence pad, sanitary napkin, or the like, wherein the structure comprises hydrophilic fibers and particles of superabsorbent material, the structure itself having a front portion and a back portion, and the padding part has a wetting region formed on the part of the padding part where the liquid discharged during use is directed, the absorbent structure itself also contains superabsorbents which are encapsulated with a material which is slowly soluble and / or which can penetrate slowly. with the liquid to be absorbed and the superabsorbent particles will not swell substantially until the coating has dissolved and / or become permeable to the liquid.

The so-called superabsorbents are a variety of polymers that are capable of absorbing a quantity of liquid that is several times their weight. They are also capable of retaining absorbed fluid even when exposed to external compression. Such polymers are widely used in various sanitary absorbent products, such as diapers, sanitary napkins and the like. These polymers are generally present in particulate form, such as in the form of granules, granules, flakes or fibers, and mixed with or layered with other absorbent materials, typically cellulosic fibers.

The effectiveness of superabsorbent materials in absorbent structures depends on many factors, such as how the superabsorbent materials are arranged in the absorbent structure itself, and their effectiveness depends on the particle shape, physical and chemical parameters, and their effectiveness. the rate at which the liquid is absorbed depends on the strength of the gel bases and the ability to retain the absorbed liquid. The absorption capacity of absorbent member fiber structures which also contain superabsorbents is adversely affected by the so-called gel blocking phenomenon. By gel blocking phenomenon, it is understood that superabsorbent particles, when wetted, form a gel which clogs the pores of the fiber structure or that the particles are arranged to prevent the fluid from spreading from the wetting area to the absorbent part. essentially prevent the liquid medium from reaching all the particles.

Another problem associated with superabsorbent materials is that the superabsorbent particles located in the wetting region of the absorbent structure bind the fluid entering this region at the first wetting. They will no longer be able to absorb more liquid when the next wetting occurs. The consequence of this is that the total absorption capacity of the absorbent member may not be optimally utilized, which ultimately results in the risk of liquid leaking from the product. This problem becomes truly significant when the product is used for a longer period of time by the wearer, for example overnight, where wetting occurs more frequently, meaning that the user drains fluid several times.

FR-A-627 080 discloses superabsorbent particles enclosed in a protective membrane which can only dissolve very slowly in the liquid and thus slowly absorb, for example, urine. The activation of the superabsorbent material is thus delayed. The encapsulated superabsorbent particles can be admixed with the unabsorbed superabsorbent particles, i.e., in the normal state, or layered such that they are located in the layer closest to the user of the absorbent member.

It is known from EP-B-0,388,120 that superabsorbent particles can be mixed with porous silica powder to reduce the hygroscopic parameters of the superabsorbent particles during storage and transport. It is also indicated in this specification that the absorption parameters of the particles are not affected by this treatment.

WO 91/04361 is used to introduce superabsorbent particles into a protective membrane and encapsulate it by said membrane. The protective membrane is a mixture of a film-forming polymer and a hydrophobic crystalline material and serves to protect the particles from absorbing liquid during the production of the absorbent structure when wet-layered during manufacture. After the structure has been dried, it is necessary to remove this cover, for example, either mechanically or thermally, for example by means of ultrasound, or the like, in order to reactivate the superabsorbent particles as fluid-absorbing particles.

US-A-4,548,847 discloses superabsorbents in the form of anion polyelectrolytes which are reversibly crosslinkable with polyvalent metal cations. The article also contains a substance which, when the product comes into contact with a liquid medium, reacts with or binds metal cations to form a complex compound. However, we did not find that the superabsorbent was activated and was able to absorb the liquid. After all, this fact results in a very short delay in the absorption process.

It is an object of the present invention to provide an absorbent article in which the transfer of the liquid medium from the wetting region of the absorbent structure to portions outside the wetting region is readily accomplished, and this is also the case with repeated wetting of the absorbent article.

The object is achieved by providing the superabsorbent material with a delayed activation time and

21 is generally localized to or close to the wetting region of the absorbent structure and other superabsorbent materials known per se, i.e., which are not encapsulated, are located in portions of the structure outside the wetting region of the structure, or they are essentially outside. Each superabsorbent particle is surrounded by a coating of material which dissolves slowly and / or is slowly absorbed by the liquid medium. Alternatively, various superabsorbent particles can be embedded in a common matrix of material.

Up to 30%, preferably up to 20%, more preferably up to 10% of the superabsorbent particles are reached by the liquid after five minutes. The test was performed according to the method used for the tea bags. A much longer delay time, such as a delay of one or more hours, before a particle begins to absorb the liquid to a greater extent after contact with the liquid medium may be desirable, and may be desirable for several hours. The coating comprising the superabsorbent particles may be, for example, gelatin, microcrystalline cellulose, cellulose derivative or surfactant.

Accordingly, the present invention relates to an absorbent structure for an absorbent article, such as a diaper, incontinence pad, sanitary napkin, or the like, wherein the structure comprises hydrophilic fibers and particles of superabsorbent material, the structure itself having a front and a back portion and the padding part has a wetting region formed on the part of the padding part where the liquid discharged during use is directed, the absorbent structure itself also contains superabsorbents which are encapsulated with a material which is slowly soluble and / or which can penetrate slowly. with the liquid to be absorbed, and the superabsorbent particles will not swell substantially until the coating material has dissolved and / or become permeable to the liquid.

The essence of the absorbent structure is that a superabsorbent with a delayed activation time is disposed within or near the wetting region of the absorbent structure and is positioned within portions of the structure outside the wetting region without conventional encapsulation.

It is preferred that those portions of the structure that contain the delayed-release superabsorbent also contain conventional superabsorbents in a given value, and that the delayed-activation superabsorbent is located in the lower portion of the structure.

Preferably, the structure comprises a liquid absorbent layer comprising a superabsorbent with a delayed activation time.

Preferred is an embodiment wherein the structure comprises two or more superabsorbents with different delayed activation times, either mixed substantially homogeneously or at different concentrations in different parts of the structure.

The absorbent structure may also be formed such that the first superabsorbent having the longest activation time is located substantially in or near the wetting region of the structure or in the upper region of the structure closest to the wearer during use, while another superabsorbent, having a shorter activation time than the former, being located substantially on the part of the structure which is outside the areas containing the first superabsorbent, and the conventional superabsorbent being located substantially away from the wetting region.

The superabsorbent material may be wrapped or wrapped in gelatin, microcrystalline cellulose, cellulose derivatives, or surfactant coatings.

According to a preferred embodiment of the present invention, the retarded activity of the superabsorbent material occurs in a layer located on the lower part of the absorbent structure, which layer is capable of acting as a fluid-receiving and fluid-absorbing layer. The liquid-absorbing layer may also be located below or above the structure. The liquid spreading layer itself contains superabsorbents which have a delayed activation time and may function as a spare capacity, however, in the event that the article is rewetted, but does not prevent the liquid from being absorbed.

The structure itself may contain two or more superabsorbent materials with different delayed activation times.

The invention will now be described in more detail by way of exemplary embodiments, in the accompanying drawings. The

Figure 1 is a top view of a diaper, the side being closer to the wearer during use,

2-4. Figures 1 to 4 are cross-sectional views of an absorption layer used in various embodiments of the invention,

Figures 5 and 6 show the change in the concentration of superabsorbent material in the longitudinal direction of the diaper in various embodiments of the invention.

Figure 1 shows a top view of a diaper having a liquid-permeable layer 1, for example made of a nonwoven product or a perforated plastic film, and having a liquid impermeable layer 2, such as a plastic film or hydrophobic nonwoven product; the absorbent member 3 is disposed.

The diaper is designed to be positioned at the wearer's lower body to form an essentially absorbent underwear. For this purpose, the diaper is further provided with a back portion 4 which lies on the backside of the wearer, a front portion 5 which lies on the front part of the wearer's body and has a

This is the part of the step pad which is located between the back part 4 and the front part 5 and which, when underwear, is worn by the wearer in the step pad part. Like diaper products, the diaper may be fastened with fastening tabs 7 located at the back 4 and thus at the waist 8. These fastening tongues 7 can then be fastened to the front portion 5 during use, close to the front waist portion 9, so that the diaper is properly secured around the body during wear.

The diaper shown in Figure 1 further comprises pre-tensioned elastic members 10, which may be elastic bands or elastic fibers with an outer wrap, elastic foam, or the like, known in the art. For the sake of simplicity, the elastic member 10 will be shown in Fig. 1 when stretched. The moment the tension in the elastic members 10 is released, it contracts and eventually results in a suitable elastic closure around the foot.

In the embodiment shown in Fig. 1, the absorbent member 3 comprises two layers, an upper fluid receiving layer 11 and a lower fluid suction and fluid storage layer 12. The upper fluid receiving layer 11 must be capable of absorbing a large amount of fluid in a very short time, i.e., having a very high instantaneous fluid absorption capacity, while the lower fluid receiving and fluid storage layer 12 must have a high fluid holding capacity and it must be capable of extracting the liquid from the fluid receiving layer 11 and storing it properly distributed. The difference in the parameters of the layers 11 and 12 can also be achieved by a difference in their density, whereby a more compacted fiber structure can distribute the liquid more efficiently than the same fiber structure when it has a lower density, e.g., with a larger pore size. instantaneous fluid absorption capacity, but less fluid retention capacity. The difference in absorption parameters between the two layers 11 and 12 can also be achieved with different fiber structures having different parameters. Thus, for example, chemically produced cellulosic fleece is capable of distributing the liquid medium to a greater extent than mechanical fiber fleece or chemical thermo-mechanical fiber web, so-called CTMP. The fiber structure of chemically stiffened cellulosic fibers also has a high instantaneous liquid-absorbing capacity, but will have a lower liquid-dispersive capacity than conventional chemical fiber webs. The liquid-receiving layer 11 may be made of synthetic or natural fibers or even of fluffed nonwoven. The liquid receiving layer 11 may not need to contain a superabsorbent material, but it may be desirable to include all superabsorbent materials. In the liquid receiving layer 11, the superabsorbent material may comprise from 2 to 30%, preferably 2 to 15%, relative to the total weight of the superabsorbent material relative to the dry state of the all layer, where superabsorbent is used. The superabsorbent material in layer 11 is generally uniformly distributed over at least one region and serves to absorb and bind the fluid that remains in layer 11 after the second fluid absorber and fluid storage layer 12 has already aspirated the liquid. . Since the liquid-receiving layer 11 contains superabsorbents, a very dry surface can be achieved since the fluid is drawn from the interstices and the layers. The superabsorbent particles in layer 11 preferably have high gel strength, i.e., they are capable of expanding, swelling and retaining the fluid properly, and do not disintegrate or block the fluid under pressure when applied in normal use. These superabsorbents are characterized by their high degree of crosslinking, that is, it is much more difficult to compress the superabsorbents than when the gel has a lower strength or a lower degree of crosslinking.

The liquid suction and liquid storage layer 12 also contains superabsorbent materials. The superabsorbent content of the layer 12 is from 2 to 90%, preferably from 10 to 80%, relative to the total weight of the layer 12 in the dry state. In the exemplary embodiment of Figure 2, the layer 12 comprises two different types of superabsorbents 14 and 15. Layer 12, for ease of understanding of the subject matter of the invention, comprises a first superabsorbent 14, which is located in Figure 1 around the wetting region 16 of the diaper, i.e., in the area where it contacts the wearer's skin, and where the liquid is drained. This wetting region 16 is generally located slightly behind the front portion of the diaper, and the particles are encapsulated in a material which dissolves only very slowly when it comes into contact with the liquid to be absorbed or the liquid can penetrate its wall very slowly. Examples of such body fluids are urine. The encapsulated superabsorbents 14 will not swell and will absorb the liquid until the outer casing has dissolved and / or the liquid has penetrated through it. The fluid-absorbing layer 11 may also include encapsulated superabsorbents 14, which acts as a spare capacity for diaper rehydration.

The term superabsorbent is to be understood in the broad sense of the invention and any superabsorbent material can be used, i.e., superabsorbent material in the form of granules, granules, flakes or even short fibers. The superabsorbent material may comprise water-insoluble cross-linked polymers substantially chemically prepared and a variety of other chemical compounds. The superabsorbent compounds are not of major importance for the present invention as any encapsulated superabsorbent 14 may be used which has parameters that are consistent with the intended purpose. Of course, a mixture of different superabsorbent materials is also added4

HU215 810Β can be used. In any case, the superabsorbent should be one that has a suitable delayed activation time, i.e., the swelling and fluid absorption of the superabsorbent 14 does not occur to some extent when the diaper is first wetted, so it will essentially retain its original particle size. . This means that the product does not prevent the liquid medium from spreading to the remainder of the liquid suction and storage layer 12 from the wetting region 16, where the layer 12 contains conventional superabsorbents 15 which immediately begin to absorb the liquid upon contact with the liquid. or a few seconds after contacting the liquid. After a subsequent discharge of liquid onto the diaper, the encapsulated superabsorbents 14 are substantially unused and do not prevent the fluid from spreading and spreading, but then begin to swell and absorb some of the fluid provided that it is delayed in activation. the delay time for the superabsorbent 14 has already passed.

The time required to activate the encapsulated superabsorbent 14 will depend upon the material selected which surrounds the superabsorbent 14, the thickness of the casing, so that the delay time may be selected to take into account these parameters. The activation time is generally selected and adapted to the amount of time that normally elapses before the second fluid is discharged, which can usually be several hours. The activation time at least corresponds to the time required after the first liquid emptying from the wetting region 16 for the liquid to spread to the second layer 12, which layer contains the conventional superabsorbents 15 and can absorb most of the liquid. This time is at least 5 minutes, but preferably at least minutes. More preferably, however, the activation time is at least one hour. However, the activation time can also be set according to the type of product and the length of time the product is intended to be used, i.e. how long the user will wear it.

The so-called tea bag test procedure is suitable for measuring the activation time. According to this method, 0.2 g of superabsorbent is placed in a pouch made of polyester mesh, 5 x 5 cm, and the pouch itself is properly sealed along its rim. Subsequently, the sachet was placed in a container containing 0.9% sodium chloride solution and the sample material began to swell freely in the sachet. The sample used as an example should not be so large that the pouch itself limits its absorption in some form. Samples were removed from the saline solution for a period of time, then the solution was allowed to drip for a minute and the pouch was weighed. The measurement procedure is considered complete when two consecutive measurements indicate that more fluids are no longer absorbed by the material, ie it can be demonstrated that the full capacity of the superabsorbent material has been used to absorb the liquid.

The absorption capacity A, (g / g) for superabsorbent materials can be calculated as follows:

A ₁ = (W ₁ -W ₂ ) / 0.2 where W j is the mass of the tea bag and the sample after absorption, W ₂ is the mass of the tea bag and 0.2 is the dry mass of the sample.

In this case, the activation time is defined as the time required for a given superabsorbent to utilize a given fraction of its total absorption capacity. In the present invention, the superabsorbent used up to 30%, preferably up to 20%, more preferably up to 10% of its total absorption capacity in most cases after 5 minutes, in other cases this time period is 15 minutes, or optionally it may take more than an hour.

The material used to encapsulate the superabsorbents may be, for example, similar to those used to encapsulate delayed-release drugs, for example, gelatin capsules, the coating may be microcrystalline cellulose, cellulose derivatives, surfactant coatings, or any other material which is slowly degradable or slowly wetting it from the liquid it will absorb. The casing itself may be a material which is slowly soluble or insoluble in the liquid to be absorbed, but has a porosity which allows the liquid medium to slowly penetrate the material. When the encapsulated superabsorbent particles come into contact with the liquid medium, they begin to swell slowly and, if necessary, their casing may crack.

The interface between the various superabsorbents 14 and 15 may be continuous or intermittent within the layer 12 such that the superabsorbents 14 and 15 are mixed with one another in the transition region.

In the exemplary embodiment of Figure 3, the encapsulated superabsorbents 14 are located in and around the wetting region 16, but only in the upper portion of the layer 12, while the conventional superabsorbents 15 are located outside the wetting region 16 and lower located on the side opposite to the wetting region 16.

Figure 4 shows a further embodiment wherein the encapsulated superabsorbents 14 are disposed in the wetting region 16 so that they are also located on the lower portion of the layer 12. However, this arrangement will not prevent the liquid medium from spreading in the lower part of the layer 12 and the liquid will be able to diffuse in such a layer to the same extent as a layer of normal pure fiber web. Activation of the superabsorbents 14 allows full absorption of the substantially unused absorption capacity of a given product. Optionally, if there is a separate absorbent layer

HU215 810Β is also placed below or above the storage layer. This liquid absorbent layer may also include superabsorbents 14 which retain their liquid absorbent capacity for the time that the wearer is repeatedly discharging liquid.

Various encapsulated superabsorbents 14 may be used, which may have different activation times. The superabsorbents 14, which have a longer activation time, are located in the wet zone 16, while the other superabsorbents 14, which have a shorter activation time, are located outside. Of course, other other arrangements may be feasible. The superabsorbents 14 which have the shortest absorption time are always located away from the wet region 16. In this case, the activation time can be set to anticipate when the product is to be worn after the first dehydration or after a third, etc. moisture. The interface between the various superabsorbents 14 and 15 need not be completely delimited, but there may be a continuous transition where a mixture of different superabsorbents 14 and 15 is present in certain portions of the absorbent layer. The superabsorbent mixture can also be used with different activation times throughout or in particular portions of the absorbent core.

Figure 5 shows a function where the vertical axis shows the concentration of different superabsorbents 14 and 15 and the horizontal axis shows the change in superabsorbent concentration in the exemplary embodiment along the diaper longitudinal direction of the liquid suction and fluid storage layer 12. In the illustrated embodiment, the maximum concentration of the encapsulated superabsorbents 14, whose concentration change and gradient is indicated by long dashed lines, is in the range of wetness 16 and hence decreases gradually towards the front and back portions of the layer 12. For conventional superabsorbents 15, the concentration describes an alternating maximum and minimum curve, the highest concentration being in the range just outside the wet range 16, the concentration in the wet range being relatively low, and then the concentration value is gradually decreasing towards the hindquarters.

The resulting concentration change resulting from the combined use of the superabsorbents 14 and 15 is shown in Figure 5 by the solid line. The solid line clearly shows that the resultant concentration is lowest in the 16 wetted range, increasing to these portions on the outside and then decreasing again to the edges of the diaper. This arrangement allows a very good utilization of the superabsorbents 14 and 15.

Fig. 6 illustrates an example where the concentration of encapsulated superabsorbent material 14 is selected to be high in the wetting region 16 and low in the areas outside the wetting region 16 but the concentration of the other superabsorbent material 15 is adjusted to the resulting concentration, again indicated by the solid line, should provide a perfectly uniform distribution in the middle of the absorption layer 12.

The above-mentioned Figures 5 and 6 show that the wetting region 16 is located in the middle of the liquid suction and liquid storage layer 12. However, it is of course also possible to implement embodiments in which the wetting region 16 is shifted, for example towards the front of the layer 12. In this case, the gradient of concentration is correspondingly extended by them. In other cases, two or more wetting regions 16 are formed on the product, since the location of the wetting points also depends on the position of the user, i.e. lying or being present, etc.

All embodiments preferably also contain small amounts of conventional superabsorbents 15 which are located on portions of the absorbent layer 12 that also contain the encapsulated superabsorbents 14, so that, for example, superabsorbents 15 may also be present in the wetting region 16. absorb liquid remaining, i.e., which has not been absorbed by the remaining portions of the absorbent member. Conventional superabsorbents 15 may, for example, be placed in a thin region so as to form the topmost layer of layer 12 so as to ensure that the surface of the product remains dry at all times.

The present invention is primarily applicable to diapers where they are worn for a relatively longer period of time, for example overnight, with multiple drains. Of course, the essential discovery of the invention will be accomplished not only by the exemplary embodiments shown, but also by many other embodiments that will provide guidance to those skilled in the art. For example, the superabsorbents 14 and 15 may be applied in layers instead of being blended between the fibers of the structure. It is also not necessary for the superabsorbent 15 to be present in the form of a particle, for example, in the form of a sheet.

The embodiment was directed to diapers, but it is also clear that any product that serves the same purpose as a diaper, such as an incontinence pad, a sanitary napkin, or the like, is suitable for use in the present invention. My absorbent pad itself can have different shapes, and even its shape and structure can be different, made up of a single layer or multiple layers. In addition to cellulosic fibers having a fiber structure such that superabsorbents 14 and 15 can be mixed therein, other preferably hydrophilic fibers, either natural or synthetic, may be present. Any fiber having absorption parameters suitable for the present invention may be used. For example, the superabsorbent itself may be sandwiched between layers of tissue.

Claims (7)

An absorbent structure for an absorbent article, such as a diaper, incontinence pad, sanitary napkin or the like, wherein the structure comprises hydrophilic fibers and particles of superabsorbent material, the structure itself having a front portion (4) and a rear portion (5), and the padding portion (6), the stepping portion (6) having a wetting region (16) formed on the portion of the stepping portion (6) to which the liquid discharged during use is directed, the absorbent structure itself having superabsorbents which they are encapsulated with a material which is slowly soluble and / or which is permeable to the liquid to be absorbed slowly and the superabsorbent particles will not substantially swell until the coating material is soluble and / or permeable to the liquid, characterized by to delayed activation The time-absorbent superabsorbent (14) is disposed in or adjacent to the wetting region (16) of the absorbent structure and is a conventional uncoated superabsorbent (15) located in portions of the structure outside the wetting region (16). 2. The absorbent structure of claim 1, wherein the portions of the structure comprising the superabsorbent (14) having a delayed activation time also contain conventional superabsorbents (15). An absorbent structure according to claim 1 or 2, characterized in that the superabsorbent (14) with a delayed activation time is located in the lower part of the structure. 4. An absorbent structure according to any one of claims 1 to 4, characterized in that the structure comprises a liquid absorbent layer (12) comprising a superabsorbent (14) with a delayed activation time. 5. An absorbent structure according to any one of claims 1 to 3, characterized in that it contains two or more superabsorbents (14) with different delayed activation times, either in a substantially homogeneous mixture or at different concentrations in different parts of the structure. An absorbent structure according to claim 5, characterized in that the first superabsorbent (14) having the longest activation time is located substantially in or near the wetting region (16) of the structure or during use of the structure. in the upper region closest to its wearer, while a second superabsorbent (14) having a shorter activation time than the former is disposed substantially in the part of the structure which is outside the portions containing the first superabsorbent (14); located substantially away from the wetting region (16). 7. A superabsorbent material according to any one of claims 1 to 3, characterized in that the superabsorbent material is encapsulated or coated with gelatin, microcrystalline cellulose, cellulose derivative or surfactant.